This work is licensed under the Creative Commons Attribution 4.0 International License.
Bongers, T. 1990. The maturity index: An ecological measure of environmental disturbance based on nematode species composition. Oecologia 83:14–19.BongersT.1990The maturity index: An ecological measure of environmental disturbance based on nematode species composition831419Search in Google Scholar
Bongers, T., and Bongers, M. 1998. Functional diversity of nematodes. Applied Soil Ecology 10: 239–251.BongersT.andBongersM.1998Functional diversity of nematodes10239251Search in Google Scholar
Bongers, T., and Ferris, H. 1999. Nematode community structure as a bioindicator in environmental monitoring. Trends in Ecology & Evolution 14:224–228.BongersT.andFerrisH.1999Nematode community structure as a bioindicator in environmental monitoring14224228Search in Google Scholar
Borůvka, L., Kozak, J., Kristoufkova, S., and Huan-Wei, C. 1996. Heavy contamination of soil with cadmium, lead and zinc in the alluvium of the Litavka River [Czech Republic]. Rostlinna Vyroba-UZPI (Czech Republic).BorůvkaL.KozakJ.KristoufkovaS.andHuan-WeiC.1996Search in Google Scholar
Borůvka, L., and Vacha, R. 2006. Litavka River alluvium as a model area heavily polluted with potentially risk elements. Pp. 267–298 in J. L. Morel, J. L., Echevarria, G., and Goncharova, N. eds. Phytoremediation of metal-contaminated soils. Dordrecht: Springer.BorůvkaL.andVachaR.2006Litavka River alluvium as a model area heavily polluted with potentially risk elementsPp267298inL. MorelJ.JL., Echevarria.G., andGoncharovaN.edsDordrechtSpringerSearch in Google Scholar
Campbell, C. D., Warren, A., Cameron, C. M., and Hope, S. J. 1997. Direct toxicity assessment of two soils amended with sewage sludge contaminated with heavy metals using a protozoan (Colpoda steinii) bioassay. Chemosphere 34:501–514.CampbellC. D.WarrenA.CameronC. M.andHopeS. J.1997Direct toxicity assessment of two soils amended with sewage sludge contaminated with heavy metals using a protozoan (Colpoda steinii) bioassay34501514Search in Google Scholar
Chapman, E. E. V., Dave, G., and Murimboh, J. D. 2013. A review of metal (Pb and Zn) sensitive and pH tolerant bioassay organisms for risk screening of metal-contaminated acidic soils. Environmental Pollution 179:326–342.ChapmanE. E. V.DaveG.andMurimbohJ. D.2013A review of metal (Pb and Zn) sensitive and pH tolerant bioassay organisms for risk screening of metal-contaminated acidic soils179326342Search in Google Scholar
Cobb, N. A. 1918. Estimating the nematode population of the soil. Agric Tech Circ Bur Pl Ind US Dep Agric No.1 48 ppCobbN. A.1918Search in Google Scholar
Dlouhá, Š., Petrovský, E., Kapička, A., Borůvka, L., Ash, C., and Drábek, O. 2013. Investigation of polluted alluvial soils by magnetic susceptibility methods: A case study of the Litavka River. Soil and Water Research 8:151–157.DlouháŠ.PetrovskýE.KapičkaA.BorůvkaL.AshC.andDrábekO.2013Investigation of polluted alluvial soils by magnetic susceptibility methods: A case study of the Litavka River8151157Search in Google Scholar
Fajardo, C., Costa, G., Nande, M., Martín, C., Martín, M., and Sánchez-Fortún, S. 2019. Heavy metals immobilization capability of two iron-based nanoparticles (nZVI and Fe3O4): Soil and freshwater bioassays to assess ecotoxicological impact. Science of the Total Environment 656:421–432.FajardoC.CostaG.NandeM.MartínC.MartínM.andSánchez-FortúnS.2019Heavy metals immobilization capability of two iron-based nanoparticles (nZVI and Fe3O4): Soil and freshwater bioassays to assess ecotoxicological impact656421432Search in Google Scholar
Faměra, M., Kotková, K., Tůmová, Š., Elznicová, J., and Grygar, T. M. 2018. Pollution distribution in floodplain structure visualised by electrical resistivity imaging in the floodplain of the Litavka River, the Czech Republic. Catena 165:157–172.FaměraM.KotkováK.TůmováŠ.ElznicováJ.andGrygarT. M.2018Pollution distribution in floodplain structure visualised by electrical resistivity imaging in the floodplain of the Litavka River, the Czech Republic165157172Search in Google Scholar
Ferris, H. 2010. Form and function: metabolic footprints of nematodes in the soil food web. European Journal of Soil Biology 46:97–104.FerrisH.2010Form and function: metabolic footprints of nematodes in the soil food web4697104Search in Google Scholar
Ferris, H., Bongers, T., and De Goede, R. G. M. 2001. A framework for soil food web diagnostics: Extension of the nematode faunal analysis concept. Applied Soil Ecology 18:13–29.FerrisH.BongersT.andDe GoedeR. G. M.2001A framework for soil food web diagnostics: Extension of the nematode faunal analysis concept181329Search in Google Scholar
Fröhlichová, A., Száková, J., Najmanová, J., and Tlustoš, P. 2018. An assessment of the risk of element contamination of urban and industrial areas using Taraxacum sect. Ruderalia as a bioindicator. Environmental Monitoring and Assessment 190:1–14.FröhlichováA.SzákováJ.NajmanováJ.andTlustošP.2018An assessment of the risk of element contamination of urban and industrial areas using Taraxacum sect190114Search in Google Scholar
Gutiérrez, C., Fernández, C., Escuer, M., Campos-Herrera, R., Rodríguez, M. E. B., Carbonell, G., and Martín, J. A. R. 2016. Effect of soil properties, heavy metals and emerging contaminants in the soil nematodes diversity. Environmental Pollution 213:184–194.GutiérrezC.FernándezC.EscuerM.Campos-HerreraR.RodríguezM. E. B.CarbonellG.andMartínJ. A. R.2016Effect of soil properties, heavy metals and emerging contaminants in the soil nematodes diversity213184194Search in Google Scholar
Háněl, L. 2004. Colonization of chemical factory wastes by soil nematodes. Pedobiologia 48:373–381.HánělL.2004Colonization of chemical factory wastes by soil nematodes48373381Search in Google Scholar
Kašpárek, L. 1984. About the floods of 1872 and 1981 on Litavka River and their importance for estimation of Nyear floods. Práce a Studie ČHMÚ 7:1– 56 In Czech.KašpárekL.1984About the floods of 1872 and 1981 on Litavka River and their importance for estimation of Nyear floods7156In CzechSearch in Google Scholar
Kebonye, N. M., Eze, P. N., John, K., Agyeman, P. C., Němeček, K., and Borůvka, L. 2021. An in-depth human health risk assessment of potentially toxic elements in highly polluted riverine soils, Příbram (Czech Republic). Environmental Geochemistry and Health 44:369–385.KebonyeN. M.EzeP. N.JohnK.AgyemanP. C.NěmečekK.andBorůvkaL.2021An in-depth human health risk assessment of potentially toxic elements in highly polluted riverine soils, Příbram (Czech Republic)44369385Search in Google Scholar
Korthals, G. W., Bongers, M., Fokkema, A., Dueck, T. A., and Lexmond, T. M. 2000. Joint toxicity of copper and zinc to a terrestrial nematode community in an acid sandy soil. Ecotoxicology 9:219–228.KorthalsG. W.BongersM.FokkemaA.DueckT. A.andLexmondT. M.2000Joint toxicity of copper and zinc to a terrestrial nematode community in an acid sandy soil9219228Search in Google Scholar
Kotková, K., Nováková, T., Tůmová, Š., Kiss, T., Popelka, J., and Faměra, M. 2019. Migration of risk elements within the floodplain of the Litavka River, the Czech Republic. Geomorphology 329:46–57.KotkováK.NovákováT.TůmováŠ.KissT.PopelkaJ.andFaměraM.2019Migration of risk elements within the floodplain of the Litavka River, the Czech Republic3294657Search in Google Scholar
Li, Q., Jiang, Y., and Liang, W. J. 2006. Effect of heavy metals on soil nematode communities in the vicinity of a metallurgical factory. Journal of Environmental Sciences 18:323–328.LiQ.JiangY.andLiangW. J.2006Effect of heavy metals on soil nematode communities in the vicinity of a metallurgical factory18323328Search in Google Scholar
Martinez, J. G., Torres, M. A., dos Santos, G., and Moens, T. 2018. Influence of heavy metals on nematode community structure in deteriorated soil by gold mining activities in Sibutad, southern Philippines. Ecological Indicators 91:712–721.MartinezJ. G.TorresM. A.dos SantosG.andMoensT.2018Influence of heavy metals on nematode community structure in deteriorated soil by gold mining activities in Sibutad, southern Philippines91712721Search in Google Scholar
Mayerová, M., Petrová, Š., Madaras, M., Lipavský, J., Šimon, T., and Vaněk, T. 2017. Non-enhanced phytoextraction of cadmium, zinc, and lead by high-yielding crops. Environmental Science and Pollution Research 24:14706–14716.MayerováM.PetrováŠ.MadarasM.LipavskýJ.ŠimonT.andVaněkT.2017Non-enhanced phytoextraction of cadmium, zinc, and lead by high-yielding crops241470614716Search in Google Scholar
Nisa, R. U., Tantray, A. Y., Kouser, N., Allie, K. A., Wani, S. M., Alamri, S. A., and Shah, A. A. 2021. Influence of ecological and edaphic factors on biodiversity of soil nematodes. Saudi Journal of Biological Sciences 28:3049–3059.NisaR. U.TantrayA. Y.KouserN.AllieK. A.WaniS. M.AlamriS. A.andShahA. A.2021Influence of ecological and edaphic factors on biodiversity of soil nematodes2830493059Search in Google Scholar
Park, B. Y., Lee, J. K., Ro, H. M., and Kim, Y. H. 2011. Effects of heavy metal contamination from an abandoned mine on nematode community structure as an indicator of soil ecosystem health. Applied Soil Ecology 51:17–24.ParkB. Y.LeeJ. K.RoH. M.andKimY. H.2011Effects of heavy metal contamination from an abandoned mine on nematode community structure as an indicator of soil ecosystem health511724Search in Google Scholar
Paton, G. I., Viventsova, E., Kumpene, J., Wilson, M. J., Weitz, H. J., and Dawson, J. J. 2006. An ecotoxicity assessment of contaminated forest soils from the Kola Peninsula. Science of the Total Environment 355:106–117.PatonG. I.ViventsovaE.KumpeneJ.WilsonM. J.WeitzH. J.andDawsonJ. J.2006An ecotoxicity assessment of contaminated forest soils from the Kola Peninsula355106117Search in Google Scholar
Pen-Mouratov, S., Shukurov, N., and Steinberger, Y. 2008. Influence of industrial heavy metal pollution on soil free-living nematode population. Environmental Pollution 152:172–183.Pen-MouratovS.ShukurovN.andSteinbergerY.2008Influence of industrial heavy metal pollution on soil free-living nematode population152172183Search in Google Scholar
Quevauviller, P., Ure, A., Muntau, H., and Griepink, B. 1993. Improvement of analytical measurements within the BCR-programme: Single and sequential extraction procedures applied to soil and sediment analysis. International Journal of Environmental Analytical Chemistry 51:129–134.QuevauvillerP.UreA.MuntauH.andGriepinkB.1993Improvement of analytical measurements within the BCR-programme: Single and sequential extraction procedures applied to soil and sediment analysis51129134Search in Google Scholar
Renčo, M., and Čerevková, A. 2015. Long-term effects of a wildfire on the soil nematode communities in the spruce forest ecosystem of High Tatra National Park. International Journal of Wildland Fire 24:702–711.RenčoM.andČerevkováA.2015Long-term effects of a wildfire on the soil nematode communities in the spruce forest ecosystem of High Tatra National Park24702711Search in Google Scholar
Renčo, M., Čerevková, A., Homolová, Z., and Gömöryová, E. 2015. Long-term effects on soil nematode community structure in spruce forests of removing or not removing fallen trees after a windstorm. Forest Ecology and Management 356:243–252.RenčoM.ČerevkováA.HomolováZ.andGömöryováE.2015Long-term effects on soil nematode community structure in spruce forests of removing or not removing fallen trees after a windstorm356243252Search in Google Scholar
Rodríguez Martín, J. A., Gutiérrez, C., Escuer, M., García-González, M. T., Campos-Herrera, R., and Águila, N. 2014. Effect of mine tailing on the spatial variability of soil nematodes from lead pollution in La Union (Spain). Science of the Total Environment 473:518–529.Rodríguez MartínJ. A.GutiérrezC.EscuerM.García-GonzálezM. T.Campos-HerreraR.andÁguilaN.2014Effect of mine tailing on the spatial variability of soil nematodes from lead pollution in La Union (Spain)473518529Search in Google Scholar
Šalamún, P., Kucanová, E., Brázová, T., Miklisová, D., Renčo, M., and Hanzelová, V. 2014. Diversity and food web structure of nematode communities under high soil salinity and alkaline pH. Ecotoxicology 23:1367–1376.ŠalamúnP.KucanováE.BrázováT.MiklisováD.RenčoM.andHanzelováV.2014Diversity and food web structure of nematode communities under high soil salinity and alkaline pH2313671376Search in Google Scholar
Šalamún, P., Renčo, M., Kucanová, E., Brázová, T., Papajová, I., Miklisová, D., and Hanzelová, V. 2012. Nematodes as bioindicators of soil degradation due to heavy metals. Ecotoxicology 21:2319–2330.ŠalamúnP.RenčoM.KucanováE.BrázováT.PapajováI.MiklisováD.andHanzelováV.2012Nematodes as bioindicators of soil degradation due to heavy metals2123192330Search in Google Scholar
Sánchez-Moreno, S., Camargo, J. A., and Navas, A. 2006. Ecotoxicological assessment of the impact of residual heavy metals on soil nematodes in the Guadiamar River Basin (Southern Spain). Environmental Monitoring and Assessment 116:245–262.Sánchez-MorenoS.CamargoJ. A.andNavasA.2006Ecotoxicological assessment of the impact of residual heavy metals on soil nematodes in the Guadiamar River Basin (Southern Spain)116245262Search in Google Scholar
Sánchez-Moreno, S., and Navas, A. 2007. Nematode diversity and food web condition in heavy metal polluted soils in a river basin in southern Spain. European Journal of Soil Biology 43:166–179.Sánchez-MorenoS.andNavasA.2007Nematode diversity and food web condition in heavy metal polluted soils in a river basin in southern Spain43166179Search in Google Scholar
Seinhorst, J. W. 1962. On the killing, fixation and transferring to glycerine of nematodes. Nematologica 8:29–32.SeinhorstJ. W.1962On the killing, fixation and transferring to glycerine of nematodes82932Search in Google Scholar
Shannon, C. E., and Weaver, W. 1949. The mathematical theory of information. Urbana: University of Illinois Press, 97:128–164.ShannonC. E.andWeaverW.1949The mathematical theory of information97128164Search in Google Scholar
Shao, Y., Zhang, W., Shen, J., Zhou, L., Xia, H., Shu, W., and Fu, S. 2008. Nematodes as indicators of soil recovery in tailings of a lead/zinc mine. Soil Biology and Biochemistry 40:2040–2046.ShaoY.ZhangW.ShenJ.ZhouL.XiaH.ShuW.andFuS.2008Nematodes as indicators of soil recovery in tailings of a lead/zinc mine4020402046Search in Google Scholar
Sharma, R. K., Agrawal, M., and Marshall, F. 2007. Heavy metal contamination of soil and vegetables in suburban areas of Varanasi, India. Ecotoxicology and Environmental Safety 66:258–266.SharmaR. K.AgrawalM.andMarshallF.2007Heavy metal contamination of soil and vegetables in suburban areas of Varanasi, India66258266Search in Google Scholar
Sieriebriennikov, B., Ferris, H., and de Goede, R. G. M. 2014. NINJA: An automated calculation system for nematode-based biological monitoring. European Journal Soil Biology 61:90–93.SieriebriennikovB.FerrisH.andde GoedeR. G. M.2014NINJA: An automated calculation system for nematode-based biological monitoring619093Search in Google Scholar
Smit, C. E., Schouten, A. J., Van den Brink, P. J., Van Esbroek, M. L. P., and Posthuma, L. 2002. Effects of zinc contamination on a natural nematode community in outdoor soil mesocosms. Archives of Environmental Contamination and Toxicology 42:205–216.SmitC. E.SchoutenA. J.Van den BrinkP. J.Van EsbroekM. L. P.andPosthumaL.2002Effects of zinc contamination on a natural nematode community in outdoor soil mesocosms42205216Search in Google Scholar
Ter Braak, C. J. F., and Šmilauer, P. 2012. Canoco reference manual and user´s guide: software for ordination (version 5.0). Microcomputer Power äIthaca, NY, USA), 496 pp.Ter BraakC. J. F.andŠmilauerP.2012496ppSearch in Google Scholar
TIBCO Software Inc. 2020. Data Science Workbench, version 14. http://tibco.comhttp://tibco.comSearch in Google Scholar
van Benzooijen, J. 2006. Methods and techniques for nematology. Wagenningen University, The Netherlands, p. 112.van BenzooijenJ.2006Wagenningen UniversityThe Netherlandsp112Search in Google Scholar
Vaněk, A., Borůvka, L., Drábek, O., Mihaljevič, M., and Komárek, M. 2005. Mobility of lead, zinc and cadmium in alluvial soils heavily polluted by smelting industry. Plant Soil and Environment 51:316–321.VaněkA.BorůvkaL.DrábekO.MihaljevičM.andKomárekM.2005Mobility of lead, zinc and cadmium in alluvial soils heavily polluted by smelting industry51316321Search in Google Scholar
Vyslouzilova, M., Tlustos, P., and Száková, J. 2003. Cadmium and zinc phytoextraction potential of seven clones of Salix spp. planted on heavy metal contaminated soils. Plant Soil and Environment 49:542–547.VyslouzilovaM.TlustosP.andSzákováJ.2003Cadmium and zinc phytoextraction potential of seven clones of Salix spp49542547Search in Google Scholar
Yeates, G. W. 1994. Modification and qualification of the nematode maturity index. Pedobiologia 38: 97–101.YeatesG. W.1994Modification and qualification of the nematode maturity index3897101Search in Google Scholar
Yeates, G. W., Bongers, T., De Goede, R. G., Freckman, D. W., and Georgieva, S. 1993. Feeding habits in soil nematode families and genera – An outline for soil ecologists. Journal of Nematology 25:315.YeatesG. W.BongersT.De GoedeR. G.FreckmanD. W.andGeorgievaS.1993Feeding habits in soil nematode families and genera – An outline for soil ecologists25315Search in Google Scholar
Žák, K., Rohovec, J., and Navrátil, T. 2009. Fluxes of heavy metals from a highly polluted watershed during flood events: A case study of the Litavka River, Czech Republic. Water, Air, and Soil Pollution 203:343–358.ŽákK.RohovecJ.andNavrátilT.2009Fluxes of heavy metals from a highly polluted watershed during flood events: A case study of the Litavka River, Czech Republic203343358Search in Google Scholar
Zhao, J., and Neher, D. A. 2013. Soil nematode genera that predict specific types of disturbance. Applied Soil Ecology 64:135–141.ZhaoJ.andNeherD. A.2013Soil nematode genera that predict specific types of disturbance64135141Search in Google Scholar